Device and method for current flow control for dual battery vehicle architecture

What is claimed is: 1. A device, comprising: a plurality of field effect transistor (FETs) electrically connected between a vehicle electrical system and a battery and starter circuit; and a boost converter circuit that provides a gate voltage for the plurality of FETs greater than a source voltage for the plurality of FETs by a predetermined voltage; a fast gate discharge circuit that establishes a switchable path to ground; a control circuit electrically connected to the plurality of FETs, the boost converter circuit, and the fast gate discharge circuit, wherein the control circuit includes a first state and a second state and is configured to: receive a control signal from an engine control unit, and in response to the control signal being at a first level: switches the plurality of FETs to a first state, wherein the first state allows current flow between the vehicle electrical system and the battery and starter circuit, and turns off the boost converter circuit, in response to the control signal being a second level: turns on the boost converter circuit, and switches the plurality of FETs to a second state, wherein the second state allows current flow from the battery and starter circuit to the vehicle electrical system. 2. The device according to claim 1 , wherein current flow is prohibited from flowing from the vehicle electrical system to the battery and starter circuit on a condition that the control signal is at the second level. 3. The device according to claim 1 , the control circuit further comprising a filtering circuit configured to provide standard filtering, and overvoltage, overcurrent, and reverse battery protection for the vehicle electrical system and the battery and starter circuit. 4. The device according to claim 3 , wherein the filtering circuit is electrically connected to the boost converter circuit. 5. The device according to claim 4 , the control circuit further comprising a protection circuit electrically connected to the boost converter circuit, the protection circuit is configured to turn off the plurality of FETs upon detection of a short circuit. 6. The device according to claim 5 , wherein the short circuit is detected when a voltage at the battery and starter circuit exceeds a voltage at the vehicle electrical system by a short circuit threshold. 7. The device according to claim 6 , wherein the short circuit threshold is attained when the voltage at the battery and starter circuit is equal to or higher than half the voltage at the vehicle electrical system. 8. The device according to claim 5 , wherein the fast gate discharge circuit is electrically connected to the protection circuit and the fast gate discharge circuit is configured to establish a path to ground in an event of a short circuit. 9. An apparatus, comprising: a power board including a plurality of field effect transistor (FETs) electrically connected to a vehicle electrical system current and a battery and starter current; and a control board configured to receive a control signal from an engine control unit and connected to the vehicle electrical system current and the battery and starter current, wherein the control board comprises: a boost converter module configured to provide a gate voltage for the plurality of FETs greater than a source voltage for the plurality of FETs by a predetermined voltage, and a fast gate discharge module configured to establish a switchable path to ground; and the control board is configured to output a signal to the power board, wherein the control signal at a first level is configured to switch the plurality of FETs to a first state to allow current flow between a vehicle electrical system and a battery and starter circuit, and turn off the boost converter module; and the control signal at a second level is configured to switch the plurality of FETs to a second state to allow current flow from the battery and starter circuit to the vehicle electrical system, and turn on the boost converter module. 10. The apparatus according to claim 9 , wherein current flow is prohibited from flowing from the vehicle electrical system to the battery and starter circuit on a condition that the control signal is at the second level. 11. The apparatus according to claim 9 , wherein the control board further comprising: a filtering module configured to provide filtering, and overvoltage, overcurrent and reverse battery protection for the vehicle electrical system and the battery and starter circuit; and a protection module electrically connected to the boost converter module and the fast gate discharge module via a logical circuit, wherein in an event of a short circuit the protection module is configured to simultaneously turn off the plurality of FETs and the fast gate discharge module is configured to establish a path to ground. 12. The apparatus according to claim 11 , wherein the short circuit is detected when a voltage at the battery and starter circuit exceeds a voltage at the vehicle electrical system by a short circuit threshold. 13. The apparatus according to claim 12 , wherein the short circuit threshold is attained when the voltage at the battery and starter circuit is equal to or higher than half the voltage at the vehicle electrical system. 14. The apparatus according to claim 11 , wherein the logical circuit is configured to output a shutdown signal upon detection of the short circuit by the protection module. 15. A method for current flow control in a dual battery system, the method comprising: connecting a plurality of field effect transistor (FETs) between a vehicle electrical system and a battery and starter circuit; connecting a control circuit to the plurality of FETs, wherein the control circuit comprises a boost converter circuit and a fast gate discharge circuit, receiving a control signal from an engine control unit by the control circuit; switching the plurality of FETs to a first state in response to the control signal being at a first level to allow current flow between the vehicle electrical system and a battery and starter circuit; and switching the plurality of FETs to a second state in response to the control signal being at a second level to allow current flow from the battery and starter circuit to the vehicle electrical system; wherein in the first state the method further comprises turning off the boost converter circuit and turning off the plurality of FETs, and in the second state the method further comprises turning on the boost converter circuit to boost a gate voltage for each gate of the plurality of FETs greater than a source voltage for each source of the plurality of FETs by a predetermined voltage. 16. The method according to claim 15 , wherein current flow is prohibited from flowing from the vehicle electrical system to the battery and starter circuit on a condition that the control signal is at the second level. 17. The method according the claim 15 , wherein the each source of the plurality of FETs is connected to one of the vehicle electrical system and the battery and starter circuit. 18. The method according to claim 16 , further comprising: detecting a short circuit condition by determining if a voltage at the battery and starter circuit exceeds a voltage at the vehicle electrical system by a short circuit threshold; generating a shutdown signal; and simultaneously turning off the plurality of FETs and establishing a fast gate discharge path to ground upon detection of a short circuit. 19. The method according to claim 18 ,